/*
 *	linux/arch/alpha/kernel/sys_nautilus.c
 *
 *	Copyright (C) 1995 David A Rusling
 *	Copyright (C) 1998 Richard Henderson
 *	Copyright (C) 1999 Alpha Processor, Inc., (David Daniel, Stig Telfer, Soohoon Lee)
 *
 * Code supporting NAUTILUS systems.
 *
 *
 * NAUTILUS has the following I/O features:
 *
 * a) Driven by AMD 751 aka IRONGATE (northbridge):
 *     4 PCI slots
 *     1 AGP slot
 *
 * b) Driven by ALI M1543C (southbridge)
 *     2 ISA slots
 *     2 IDE connectors
 *     1 dual drive capable FDD controller
 *     2 serial ports
 *     1 ECP/EPP/SP parallel port
 *     2 USB ports
 */

#include <linux/kernel.h>
#include <linux/types.h>
#include <linux/mm.h>
#include <linux/sched.h>
#include <linux/pci.h>
#include <linux/init.h>
#include <linux/reboot.h>
#include <linux/mc146818rtc.h>

#include <asm/ptrace.h>
#include <asm/system.h>
#include <asm/dma.h>
#include <asm/irq.h>
#include <asm/bitops.h>
#include <asm/mmu_context.h>
#include <asm/io.h>
#include <asm/pci.h>
#include <asm/pgtable.h>
#include <asm/core_irongate.h>
#include <asm/hwrpb.h>

#include "proto.h"
#include "irq.h"
#include "bios32.h"
#include "machvec.h"

#define dev2hose(d) (bus2hose[(d)->bus->number]->pci_hose_index)

static void
nautilus_update_irq_hw(unsigned long irq, unsigned long mask, int unmask_p)
{
	mask |= 0x100;	/*Timer is connected to PIC int. line also on Nautilus*/
		      	/*And the timer int. handler enables PIC line */
			/*So not to get multiple timer int. sources*/
			/*Mask it all the times*/
	if (irq >= 8)
		outb(mask >> 8, 0xA1);
	else
		outb(mask, 0x21);
}

static void __init
nautilus_init_irq(void)
{
	STANDARD_INIT_IRQ_PROLOG;

	if (alpha_using_srm) {
		alpha_mv.device_interrupt = srm_device_interrupt;
		alpha_mv.kill_arch = generic_kill_arch;
	}

	enable_irq(2);			/* enable cascade */
	disable_irq(8);
}


static void __init
nautilus_pci_fixup(void)
{
/* All BIOS setups are preserved */
}

void
nautilus_kill_arch (int mode, char *restart_cmd)
{

#ifdef CONFIG_RTC
	/* Reset rtc to defaults.  */
	{
		unsigned char control;

		__cli();

		/* Reset periodic interrupt frequency.  */
		CMOS_WRITE(0x26, RTC_FREQ_SELECT);

		/* Turn on periodic interrupts.  */
		control = CMOS_READ(RTC_CONTROL);
		control |= RTC_PIE;
		CMOS_WRITE(control, RTC_CONTROL);	
		CMOS_READ(RTC_INTR_FLAGS);

		__sti();
	}
#endif

	switch(mode) {
        case LINUX_REBOOT_CMD_HALT:
		printk("Press Reset bottun");
		break;
	case LINUX_REBOOT_CMD_RESTART:
		{
			unsigned char v;
			irongate_hose_read_config_byte(0, 0x07<<3, 0x43, &v, 0);
			irongate_hose_write_config_byte(0, 0x07<<3, 0x43, v | 0x80, 0);
			outb(1, 0x92);
			outb(0, 0x92);
			printk("Press Reset button");
		}
		break;
        case LINUX_REBOOT_CMD_POWER_OFF:
                {
                        int pmuport;
                        irongate_hose_read_config_dword(0, 0x11<<3, 0x10, &pmuport, 0);
                        pmuport &= 0xfffe;
                        outl(0xffff, pmuport); /* clear pending events */
                        outw(0x2000, pmuport+4); /* power off */
                        printk("Press power button");
                }
	}

	while (1)
		;
	halt();
}

/*----------------------------------------------------------------------*/
/* Machine check handler code 
 *
 * Perform analysis of a machine check that was triggered by the EV6 CPU's
 * fault-detection mechanism. */

/* IPR structures for EV6, containing the necessary data for the
 * machine check handler to unpick the logout frame
 */


/* I_STAT */

#define EV6__I_STAT__PAR                ( 1 << 29 )


/* MM_STAT */

#define EV6__MM_STAT__DC_TAG_PERR       ( 1 << 10 )


/* DC_STAT */

#define EV6__DC_STAT__SEO               ( 1 << 4 )
#define EV6__DC_STAT__ECC_ERR_LD        ( 1 << 3 )
#define EV6__DC_STAT__ECC_ERR_ST        ( 1 << 2 )
#define EV6__DC_STAT__TPERR_P1          ( 1 << 1 )
#define EV6__DC_STAT__TPERR_P0          ( 1      )


/* C_STAT */

#define EV6__C_STAT__BC_PERR            ( 0x01 )
#define EV6__C_STAT__DC_PERR            ( 0x02 )
#define EV6__C_STAT__DSTREAM_MEM_ERR    ( 0x03 )
#define EV6__C_STAT__DSTREAM_BC_ERR     ( 0x04 )
#define EV6__C_STAT__DSTREAM_DC_ERR     ( 0x05 )
#define EV6__C_STAT__PROBE_BC_ERR0      ( 0x06 )
#define EV6__C_STAT__PROBE_BC_ERR1      ( 0x07 )
#define EV6__C_STAT__ISTREAM_MEM_ERR    ( 0x0B )
#define EV6__C_STAT__ISTREAM_BC_ERR     ( 0x0C )
#define EV6__C_STAT__DSTREAM_MEM_DBL    ( 0x13 )
#define EV6__C_STAT__DSTREAM_BC_DBL     ( 0x14 )
#define EV6__C_STAT__ISTREAM_MEM_DBL    ( 0x1B )
#define EV6__C_STAT__ISTREAM_BC_DBL     ( 0x1C )


/* take the two syndromes from the CBOX error chain and convert them
 * into a bit number */

/* NOTE - since I don't know of any difference between C0 and C1
 * I just ignore C1, since in all cases I've seen so far they are identical */

static const unsigned char ev6_bit_to_syndrome[72] =
{
    0xce, 0xcb, 0xd3, 0xd5, 0xd6, 0xd9, 0xda, 0xdc,     /* 0 */
    0x23, 0x25, 0x26, 0x29, 0x2a, 0x2c, 0x31, 0x34,     /* 8 */
    0x0e, 0x0b, 0x13, 0x15, 0x16, 0x19, 0x1a, 0x1c,     /* 16 */
    0xe3, 0xe5, 0xe6, 0xe9, 0xea, 0xec, 0xf1, 0xf4,     /* 24 */
    0x4f, 0x4a, 0x52, 0x54, 0x57, 0x58, 0x5b, 0x5d,     /* 32 */
    0xa2, 0xa4, 0xa7, 0xa8, 0xab, 0xad, 0xb0, 0xb5,     /* 40 */
    0x8f, 0x8a, 0x92, 0x94, 0x97, 0x98, 0x9b, 0x9d,     /* 48 */
    0x62, 0x64, 0x67, 0x68, 0x6b, 0x6d, 0x70, 0x75,     /* 56 */
    0x01, 0x02, 0x04, 0x08, 0x10, 0x20, 0x40, 0x80      /* 64 */
};


static int ev6_syn2bit(unsigned long c0, unsigned long c1)
{
    int bit;

    for (bit = 0; bit < 72; bit++)
        if (ev6_bit_to_syndrome[bit] == c0)	return bit;
    for (bit = 0; bit < 72; bit++)
        if (ev6_bit_to_syndrome[bit] == c1)	return bit + 64;

    return -1;                  /* not found */
}


/* single bit ECC errors are categorised here */

#if 0
static const char *interr = "CPU internal error";
static const char *slotb= "Slot-B error";
static const char *membus= "Memory/EV6-bus error";
#else
static const char *interr = "";
static const char *slotb = "";
static const char *membus = "";
#endif

static void ev6_crd_interp(char *interp, struct el_common_EV6_mcheck * L)
{

    /* Icache data or tag parity error */
    if (L->I_STAT & EV6__I_STAT__PAR) {
	sprintf(interp, "%s: I_STAT[PAR]\n Icache data or tag parity error", interr);
	return;
    }

    /* Dcache tag parity error (on issue) (DFAULT) */
    if (L->MM_STAT & EV6__MM_STAT__DC_TAG_PERR) {
	sprintf(interp, "%s: MM_STAT[DC_TAG_PERR]\n Dcache tag parity error(on issue)", interr);
	return;
    }

    /* Errors relating to D-stream set non-zero DC_STAT - mask CRD bits */
    switch (L->DC_STAT & (EV6__DC_STAT__ECC_ERR_ST | EV6__DC_STAT__ECC_ERR_LD)) 
    {

    case EV6__DC_STAT__ECC_ERR_ST:
	/* Dcache single-bit ECC error on small store */
	sprintf(interp, "%s: DC_STAT[ECC_ERR_ST]\n Dcache single-bit ECC error on small store", interr);
	return;

    case EV6__DC_STAT__ECC_ERR_LD:
	switch (L->C_STAT) {
	case 0:
	    /* Dcache single-bit error on speculative load */
	    /* Bcache victim read on Dcache/Bcache miss */
	    sprintf(interp, "%s: DC_STAT[ECC_ERR_LD] C_STAT=0\n Dcache single-bit ECC error on speculative load", slotb);
	    return;

	case EV6__C_STAT__DSTREAM_DC_ERR:
	    /* Dcache single bit error on load */
	    sprintf(interp, "%s: DC_STAT[ECC_ERR_LD] C_STAT[DSTREAM_DC_ERR]\n Dcache single-bit ECC error on speculative load, bit %d", interr, ev6_syn2bit(L->DC0_SYNDROME, L->DC1_SYNDROME));
	    return;


	case EV6__C_STAT__DSTREAM_BC_ERR:
	    /* Bcache single-bit error on Dcache fill */
	    sprintf(interp, "%s: DC_STAT[ECC_ERR_LD] C_STAT[DSTREAM_BC_ERR]\n Bcache single-bit error on Dcache fill, bit %d", slotb, ev6_syn2bit(L->DC0_SYNDROME, L->DC1_SYNDROME));
	    return;

	case EV6__C_STAT__DSTREAM_MEM_ERR:
	    /* Memory single-bit error on Dcache fill */
	    sprintf(interp, "%s (to Dcache): DC_STAT[ECC_ERR_LD] C_STAT[DSTREAM_MEM_ERR]\n Memory single-bit error on Dcache fill, Address 0x%lX, bit %d", membus, L->C_ADDR, ev6_syn2bit(L->DC0_SYNDROME, L->DC1_SYNDROME));
	    return;

	default:			/* not one of these */
	}
    default:				/* not one of these */
    }

    /* I-stream, other misc errors go on C_STAT alone */
    switch (L->C_STAT) {

    case EV6__C_STAT__ISTREAM_BC_ERR:
	/* Bcache single-bit error on Icache fill (also MCHK) */
	sprintf(interp, "%s: C_STAT[ISTREAM_BC_ERR]\n Bcache single-bit error on Icache fill, bit %d", slotb, 
		    ev6_syn2bit(L->DC0_SYNDROME, L->DC1_SYNDROME));
	return;

    case EV6__C_STAT__ISTREAM_MEM_ERR:
	/* Memory single-bit error on Icache fill (also MCHK) */
	sprintf(interp, "%s : C_STATISTREAM_MEM_ERR]\n Memory single-bit error on Icache fill addr 0x%lX, bit %d", membus, L->C_ADDR, ev6_syn2bit(L->DC0_SYNDROME, L->DC1_SYNDROME));
	return;

    case EV6__C_STAT__PROBE_BC_ERR0:
    case EV6__C_STAT__PROBE_BC_ERR1:
	/* Bcache single-bit error on a probe hit */
	sprintf(interp, "%s: C_STAT[PROBE_BC_ERR]\n Bcache single-bit error on a probe hit, addr 0x%lX, bit %d", slotb, L->C_ADDR, ev6_syn2bit(L->DC0_SYNDROME, L->DC1_SYNDROME));
	return;

    default:				/* not one of these */
    }
}


/* these are the really nasty ones... */

static void ev6_mchk_interp(char *interp, struct el_common_EV6_mcheck * L)
{
    /* Machine check errors described by DC_STAT */
    switch (L->DC_STAT) {
    case EV6__DC_STAT__TPERR_P0:
    case EV6__DC_STAT__TPERR_P1:
	/* Dcache tag parity error (on retry) */
	sprintf(interp, "%s: DC_STAT[TPERR_P0|TPERR_P1]\n Dcache tag parity error(on retry)", interr);
	return;

    case EV6__DC_STAT__SEO:
	/* Dcache second error on store */
	sprintf(interp, "%s: DC_STAT[SEO]\n Dcache second error during mcheck", interr);
	return;

    default:				/* some other kind of error */
    }

    /* Machine check errors described by C_STAT */
    switch (L->C_STAT) {
    case EV6__C_STAT__DC_PERR:		/* Dcache duplicate tag parity error */
	sprintf(interp, "%s: C_STAT[DC_PERR]\n Dcache duplicate tag parity error at 0x%lX",
			interr, L->C_ADDR);
	return;

    case EV6__C_STAT__BC_PERR:		/* Bcache tag parity error */
	sprintf(interp, "%s: C_STAT[BC_PERR]\n Bcache tag parity error at 0x%lX", slotb, L->C_ADDR);
	return;

    case EV6__C_STAT__ISTREAM_BC_ERR:
	/* Bcache single-bit error on Icache fill (also CRD) */
	sprintf(interp, "%s: C_STAT[ISTREAM_BC_ERR]\n Bcache single-bit error on Icache fill 0x%lX bit %d",
		    slotb, L->C_ADDR,
		    ev6_syn2bit(L->DC0_SYNDROME, L->DC1_SYNDROME));
	return;


    case EV6__C_STAT__ISTREAM_MEM_ERR:
	/* Memory single-bit error on Icache fill (also CRD) */
	sprintf(interp, "%s: C_STAT[ISTREAM_MEM_ERR]\n Memory single-bit error on Icache fill 0x%lX, bit %d",
		    membus, L->C_ADDR,
		    ev6_syn2bit(L->DC0_SYNDROME, L->DC1_SYNDROME));
	return;


    case EV6__C_STAT__ISTREAM_BC_DBL:
	/* Bcache double-bit error on Icache fill */
	sprintf(interp, "%s: C_STAT[ISTREAM_BC_DBL]\n Bcache double-bit error on Icache fill at 0x%lX",
			slotb, L->C_ADDR);
	return;
    case EV6__C_STAT__DSTREAM_BC_DBL:
	/* Bcache double-bit error on Dcache fill */
	sprintf(interp, "%s: C_STAT[DSTREAM_BC_DBL]\n Bcache double-bit error on Dcache fill at 0x%lX",
			slotb, L->C_ADDR);
	return;

    case EV6__C_STAT__ISTREAM_MEM_DBL:
	/* Memory double-bit error on Icache fill */
	sprintf(interp, "%s: C_STAT[ISTREAM_MEM_DBL]\n Memory double-bit error on Icache fill at 0x%lX", 
			membus, L->C_ADDR);
	return;
    case EV6__C_STAT__DSTREAM_MEM_DBL:
	/* Memory double-bit error on Dcache fill */
	sprintf(interp, "%s: C_STAT[DSTREAM_MEM_DBL]\n Memory double-bit error on Dcache fill at 0x%lX", 
			membus, L->C_ADDR);
	return;

    default:			/* something else */
    }
}


static void ev6_cpu_machine_check( unsigned long vector,
		 struct el_common_EV6_mcheck *L, struct pt_regs *regs)
{
    char interp[80];			/* buffer for interpretation details */

    /* this is verbose and looks intimidating.  Should it be printed for
     * corrected (CRD) machine checks? */

    printk(KERN_CRIT "PALcode logout frame:  "
           "MCHK_Code       %d  "
           "MCHK_Frame_Rev  %d\n"
           "I_STAT  %016lx  "
           "DC_STAT %016lx  "
           "C_ADDR  %016lx\n"
           "SYND1   %016lx  "
           "SYND0   %016lx  "
           "C_STAT  %016lx\n"
           "C_STS   %016lx  "
           "RES     %016lx  "
           "EXC_ADDR%016lx\n"
           "IER_CM  %016lx  "
           "ISUM    %016lx  "
           "MM_STAT %016lx\n"
           "PALBASE %016lx  "
           "I_CTL   %016lx  "
           "PCTX    %016lx\n"
           "CPU registers: "
           "PC      %016lx  "
           "Return  %016lx\n",
           L->MCHK_Code, L->MCHK_Frame_Rev, L->I_STAT, L->DC_STAT,
           L->C_ADDR, L->DC1_SYNDROME, L->DC0_SYNDROME, L->C_STAT,
           L->C_STS, L->RESERVED0, L->EXC_ADDR, L->IER_CM, L->ISUM,
           L->MM_STAT, L->PAL_BASE, L->I_CTL, L->PCTX,
           regs->pc, regs->r26 );

    /* Attempt an interpretation on the meanings of the fields above */
    sprintf(interp, "No interpretation available!" );
    if ( vector == SCB_Q_PROCERR )		ev6_crd_interp( interp, L );
    else if ( vector == SCB_Q_PROCMCHK )	ev6_mchk_interp( interp, L );

    printk( KERN_CRIT "interpretation: %s\n\n", interp );
}


/* Perform analysis of a machine check that arrived from the system (NMI) */

static void naut_sys_machine_check( unsigned long vector, unsigned long la_ptr,
			     struct pt_regs *regs )
{
    printk("xtime %lx\n", CURRENT_TIME);
    printk("PC %lx RA %lx\n", regs->pc, regs->r26);
    irongate_pci_clr_err();
}



/* Machine checks can come from two sources - those on the CPU and those
 * in the system.  They are analysed separately but all starts here */

void nautilus_machine_check(unsigned long vector, unsigned long la_ptr,
			    struct pt_regs *regs)
{
    char *mchk_class;
    unsigned cpu_analysis=0, sys_analysis=0;	/* interpretation flags */

    /* now for some analysis.  Machine checks fall into two classes -
     * those picked up by the system, and those picked up by the CPU.
     * add to that the two levels of severity - correctable or not
     */

    if (vector == SCB_Q_SYSMCHK && ((IRONGATE0->dramms & 0x300) == 0x300)) {
	unsigned long nmi_ctl, temp;

	/* Clear ALI NMI */
        nmi_ctl = inb(0x61);
        nmi_ctl |= 0x0c;
        outb(nmi_ctl, 0x61);
        nmi_ctl &= ~0x0c;
        outb(nmi_ctl, 0x61);
	
	temp = IRONGATE0->stat_cmd;
	temp &= ~0x100;
	IRONGATE0->stat_cmd = temp; /* write again clears error bits */
	mb();
	temp = IRONGATE0->stat_cmd;  /* re-read to force write */

	temp = IRONGATE0->dramms;
	IRONGATE0->dramms = temp; /* write again clears error bits */
	mb();
	temp = IRONGATE0->dramms;  /* re-read to force write */

	draina();
	wrmces(0x7);
	mb();
	return;
    }

    switch (vector) {
    case SCB_Q_SYSERR:
	mchk_class = "Correctable System Machine Check (NMI)";
	sys_analysis = 1;
	break;
    case SCB_Q_SYSMCHK:
	mchk_class = "Fatal System Machine Check (NMI)";
	sys_analysis = 1;
	break;

    case SCB_Q_PROCERR:
	mchk_class = "Correctable Processor Machine Check";
	cpu_analysis = 1;
	break;
    case SCB_Q_PROCMCHK:
	mchk_class = "Fatal Processor Machine Check";
	cpu_analysis = 1;
	break;

    default:
	mchk_class = "Unknown vector!";
	break;
    }

    printk(KERN_CRIT "> NAUTILUS Machine check 0x%lx [%s]\n",
	   vector, mchk_class);

    if ( cpu_analysis )	
	ev6_cpu_machine_check(  vector,
				(struct el_common_EV6_mcheck *)la_ptr,
				regs );
    if ( sys_analysis )
	naut_sys_machine_check( vector, la_ptr, regs );

    /* Tell the PALcode to clear the machine check */
    draina();
    wrmces(0x7);
    mb();
}



/*
 * The System Vectors
 */

struct alpha_machine_vector nautilus_mv __initmv = {
	vector_name:		"NAUTILUS",
	DO_EV6_MMU,
	DO_DEFAULT_RTC,
	DO_IRONGATE_IO,
	DO_IRONGATE_BUS,
	machine_check:		nautilus_machine_check,
	max_dma_address:	ALPHA_NAUTILUS_MAX_DMA_ADDRESS,

	nr_irqs:		16,
	irq_probe_mask:		(_PROBE_MASK(16) & ~0x101UL),

	update_irq_hw:		nautilus_update_irq_hw,
	ack_irq:		generic_ack_irq,
	device_interrupt:	isa_device_interrupt,

	init_arch:		irongate_init_arch,
	init_irq:		nautilus_init_irq,
	init_pit:		generic_init_pit,
	pci_fixup:		nautilus_pci_fixup,
	kill_arch:		nautilus_kill_arch,
};
ALIAS_MV(nautilus)
